A particle of mass m in a unidirectional potential field have potential energy `U(x)=alpha+2betax^(2)`, where `alpha` and `beta` are positive constants. Find its time period of oscillations.

A particle located in one dimensional potential field has potential energy function U(x)=(a)/(x^(2))-(b)/(x^(3)) , where a and b are positive constants. The position of equilibrium corresponds to x equal to

A particle of mass m moves in a one dimensional potential energy U(x)=-ax^2+bx^4 , where a and b are positive constant. The angular frequency of small oscillation about the minima of the potential energy is equal to

A body of mass m is situated in a potential field U(x)= U_(0) (1-cos alpha x) when U_(0)" and "alpha are constants. Find the time period of small oscillations.

A particle of mass (m) is executing oscillations about the origin on the x axis. Its potential energy is V(x) = k|x|^3 where k is a positive constant. If the amplitude of oscillation is a, then its time period (T) is.

The relation between time t and displacement x is t = alpha x^2 + beta x, where alpha and beta are constants. The retardation is

A particles is in a unidirectional potential field where the potential energy (U) of a particle depends on the x-coordinate given by U_(x)=k(1-cos ax) & k and 'a' are constant. Find the physical dimensions of 'a' & k .

A particle of mass m is located in a region where its potential energy [U(x)] depends on the position x as potential Energy [U(x)]=(1)/(x^2)-(b)/(x) here a and b are positive constants… (i) Write dimensional formula of a and b (ii) If the time perios of oscillation which is calculated from above formula is stated by a student as T=4piasqrt((ma)/(b^2)) , Check whether his answer is dimensionally correct.

A particle of mass m is in a uni-directional potential field where the potential energy of a particle depends on the x-coordinate given by phi_(x)=phi_(0) (1- cos ax) & 'phi_(0)' and 'a' are constants. Find the physical dimensions of 'a' & phi_(0) .

A particle of unit mass undergoes one dimensional motion such that its velocity varies according to v(x) = = beta x ^(-2n) where B and n are constants and x is the position of the particle. The acceleraion of the particle as a function of x, is given by :

A particle moves in the x-y plane according to the law x=at, y=at (1-alpha t) where a and alpha are positive constants and t is time. Find the velocity and acceleration vector. The moment t_(0) at which the velocity vector forms angle of 90^(@) with acceleration vector.